WO2019141618A1 - Filter having a volume flow sensor and signalling device - Google Patents

Abstract

The invention relates to a filter comprising a device - filter signalling device - which is intended and designed such that, in a system with a filter unit (10), it displays when the filter unit (10) needs to be changed. This occurs by means of a volume flow sensor (20).

Description

 description

FILTER WITH VOLUME FLOW SENSOR AND MESSAGE DEVICE

The invention relates to a use of a device called a filter unit or a plurality of such devices. The filter unit is here and hereinafter referred to briefly as an apparatus for filtering a gas stream, in particular an air stream, and / or for separating particles entrained with the gas stream, for example paint particles or the like.

As a filter unit, for example, an arrangement in the form of a multi-folded paper fabric is considered, as described in EP 2 532 409 A. Likewise, the filter unit is a complete paper gel filter module according to EP 2 532 409 A, that is to say a combination of the multi-layered paper layer and the outer frame which receives the paper layer. Other candidate filter units are mentioned in the following text. Other conceivable filter units are expressly not excluded due to the mention of individual concrete filter units.

Those for filtering a gas stream, in particular an air stream, and / or for separating particles entrained with the gas stream, for example paint particles or the like, are filter units which require filtration of a gas stream and / or separation of particles from the gas stream , often used in large numbers. A matrix-type placement of a plurality of filter units above and next to one another in a "filter wall" or else in a rotatable filter and filter changing device is customary, for example a device according to EP 3 062 909 B.

It is unfavorable that hitherto, when using a filter unit or a plurality of filter units, it is difficult to determine when replacement of a filter unit or a plurality of filter units is sensible or necessary. One object of the proposed innovation is to propose a solution to this problem.

This object is achieved by means of an air flow sensing device, in particular by means of a system having the features of claim 1.

An embodiment of the invention will be explained in more detail with reference to the drawing. Corresponding objects or elements are provided in all figures with the same reference numerals.

The embodiment is not to be understood as limiting the invention. Rather, changes and modifications are certainly possible within the scope of the present disclosure. Each mention of individual features of the embodiment is therefore to be read without special notice expressly as a description of optional features.

Show it

Fig. 1 shows a filter unit in the form of a filter module and a for receiving the

 Filter unit specific filter module housing and as air flow sensing device a movable flap,

Fig. 2 and

 Fig. 3 shows a filter unit and a specific for receiving the filter unit

 Housing as well as air flow sensing device a movable and / or at least partially deformable flap,

Fig. 4 shows a filter unit and a specific for receiving the filter unit

Housing as well as air flow sensing device an impeller (rotor) and 5 shows an airflow sensing device located on an input side of a filter unit.

The illustration in Figure 1 shows a simplified simplified form a filter unit 10 in the form of a filter module 10 and a specific for receiving the filter module 10 filter module housing / filter unit housing 12, the mit- below also briefly referred to as housing 12. In the representation in FIG. 1, only individual sides of the outer surface of a filter module frame 14 can be seen of the filter module 10, which filter and / or separating filter and / or separating elements receive in its interior, for example a Papiergelegefilter according to the EP 2 532 409 A1. The interior of the filter module 10, that is to say, for example, such a paper-laid filter, or generally the type of filter unit 10, does not matter in the following.

The block arrow B illustrates, on the one hand, a direction of movement along which the filter module 10 is pushed into the housing 12 and, on the other hand, a direction of a volumetric flow when the filter module 10 is used during operation as a filter and / or as a separator. The dashed lines between the filter module 10 and the housing 12 illustrate the direction of movement when the filter module 10 is pushed into the housing 12.

The inner volume of the housing 12 and the outer contour of the filter module 10, ie the outer contour of the filter module frame 14, are matched to one another such that the housing 12 receives the filter module 10 in a form-fitting or at least substantially positive fit. In any case, the cube shape of the filter module 10 and of the housing 12 shown is only an option, and likewise cuboidal geometries or other, in particular polygonal, geometries, for example a honeycomb shape, are suitable.

The filter module 10 has a side 16, which flows into during operation, and an opposite side 18, which faces the operating side 16. The side 16 which flows into during operation (the side facing the block arrow B) is referred to below as the front or front side 16 of the filter module 10 for short. The the Input / front side 16 in extension of the direction of the current flowing in the volume flow opposite side 18 is referred to as the output or rear side 18 of the filter module 10 accordingly. The output / rear side 18 of the filter module 10 is provided with a flap 20 functioning as an air flow sensing device 20.

The housing 12 is open on two opposite sides 22, 24. One of the two open sides 22 faces the Filtermo- module 10 in the perspective shown. The filter module 10 is pushed into the housing 12 up to the region of the opposite open side 24, which is correspondingly briefly referred to as the rear side 24 of the housing 12, via this open side 22, which is referred to briefly as the front side 22 of the housing 12.

The filter module 10 has a first sensor component 26 on the flap 20. An associated second sensor component 28 is located in the area of the rear side 24 of the housing 12. The position of the second sensor component 28 is selected so that it is in the region of the first sensor component 26, for example, in the case of a filter unit 10 introduced into the housing 12 such that the two sensor components 26, 28 lie opposite one another, at least in such a way that a configuration is possible in which the two sensor components 26, 28 lie opposite one another.

The flap 20 is movable, in particular pivotable. In the case of a pivotable flap 20, it is articulated to the housing 12, for example, by means of a hinge element 30 on the filter module 10, namely preferably on the filter module frame 14. The material of the filter module frame 14 optionally functions as the hinge element 30. In the case of a filter module frame 14 made of cardboard or the like, the flap 20 is made of the same material and acts as a hinge element 30, for example an adhesive strip or the like. Optionally, the flap 20 may also be integrally connected to the filter module frame 14 along an edge line. Then, as a hinge element 30, perforation or embossing of the material of the filter module frame 14 in the region of the transition from the filter module frame 14 to the flap 20 functions. The flap 20 faces, with one of its surfaces, the volume flow flowing in operation (see block arrow B). In the case of a "fresh" filter unit 10, this surface (the surface not visible in the illustration in FIG. 1) of the flap 20 is impinged by the volume flow during operation. As a result of the volumetric flow, the movable flap 20 is deflected from a rest position, that is, from a position without an inflowing volume flow.

The flap 20 may have a size, as shown in the illustration in Figure 1, so that a closed flap 20, the output / back 18 of the filter module 10 completely or at least substantially covers. Similarly, an example strip-shaped flap 20 is conceivable, which covers the output / back 18 of the filter module 10 only partially. Advantageously, the size (area) of the flap 20 is selected according to the expected volume flow, so that in a filter module 10 with a rather low volume flow, a rather large flap 20 is selected, for example, a flap 20 having a surface, as shown in FIG Figure 1 is shown. In the case of a large-area flap 20 and a low volume flow, it is ensured that the low volume flow also deflects the flap 20.

In the embodiment shown, the flap 20 "hangs" like a pendulum on the hinge element 30. In a housing 12 with a horizontally oriented bottom surface and a filter module 10 inserted into such a housing 12, such a flap 20 hangs vertically or at least substantially vertically in the rest position. where "vertical" means gravitational acceleration. In the case of a flap 20 hanging in this way, it is deflected out of the rest position when a volume flow impinges on the input / front side 16 of the filter module 10 and leaves the filter module 10 on the opposite starting / rear side 18 again Damper 20 hits.

A hanging flap 20 has the advantage that it automatically returns to its rest position without external force, that is, for example, whenever an inflowing volume flow is absent. In another realization of Mobility of the flap 20 is a return element provided, for example, a spring element or an elastically extensible element which moves the flap 20 in the event of a lack of external force in the rest position and against the restoring or spring force, the flap 20 in the case of a flowing the Volumetric flow is opened. Such a return element can simultaneously act as a hinge element 30. Likewise, a hinge element 30 independent of the return element is conceivable. In the case of a restoring element, instead of just one flap 20, a plurality of flaps 20 are also suitable.

In the embodiment shown, the sensor components 26, 28 are located on and in the region of that edge of the flap 20 which is opposite the edge hinged by means of the hinge element 30. A positioning of the sensor components 26, 28 on and in the region of the other two edges is basically also conceivable.

Automatically processable information on the position of the flap 20 is available by means of a sensor system comprising the two sensor components 26, 28. The sensor component 26 on the flap 20 is, for example, a permanent magnet and the sensor component 28 on the housing 12 is correspondingly, for example, a so-called reed contact. The switching state of such a reed contact is known to be dependent on the action of an external magnetic field. With a flap 20 in the rest position ("vertical"), the two sensor components 26, 28 are in close proximity, namely, for example, one above the other (the permanent magnet attached to the lower edge of the flap 20 above the reed contact on the housing 12). The reed contact closes due to the magnetic field of the permanent magnet. Due to the closed contact, a current can flow in a signal circuit with the reed contact. This current flow can be evaluated as a sensor signal. A resulting due to a current flow sensor signal means that the flap 20 is in the rest position. A complementary signal, that is, a resulting due to an interrupted current flow sensor signal means that the flap 20 is deflected. The sensor system 26, 28 is expressly not limited to such an embodiment. Alternatively, for example, an embodiment with a phototransistor and a light-emitting diode or the like into consideration. The phototransistor is arranged, for example, as the first sensor component 26 on the flap 20, in particular on the lower edge of the flap 20. The light-emitting diode is then correspondingly arranged on the housing 12 as a second sensor component 28. Similarly, a reverse arrangement is possible. With a flap 20 in the rest position, the light of the LED falls on the phototransistor and due to a current flow in a signal circuit with the phototransistor results in a signal indicating the rest position of the flap 20. A complementary signal, that is to say a signal which results when the phototransistor does not receive any light from the light-emitting diode, means that the flap 20 is deflected out of the rest position. In a sensor system 26, 28 with a phototransistor and a light-emitting diode, a variant is also possible, in which both parts of the sensor system 26, 28, that is to say the phototransistor and the light-emitting diode, on the flap 20 or on the housing 12, preferably on the housing 12. The phototransistor and the light-emitting diode are then facing each other, so that without an obstacle between the phototransistor and the light-emitting diode, the light from the light-emitting diode falls onto the phototransistor. In a sensor 26, 28 on the housing 12, the flap 20, for example, an extension or the like, which interrupts the beam path from the light emitting diode to the phototransistor at a located in rest position flap 20. In the case of a sensor 26, 28 arranged on the flap 20, such an extension or the like interrupting the beam path is located on the housing 12.

During operation, in the case of "fresh" filter units 10, that are not yet loaded with dust, color particles or the like inside, it is to be expected that they will be continuous for the inflowing volume flow. In the case of fresh filter units 10, therefore, in the case of each filter unit 10 having a flap 20, its flap 20 is deflected out of the rest position and, due to the sensor system 26, 28, a corresponding sensor signal results. This sensor signal (in the case of a reed contact, a sensor signal resulting from a high impedance of the signal circuit) means that the filter unit 10 is continuous or even continuous, ie that at least a part of the filter unit 10 remains on the rear side 18 of the filter unit 10 oncoming volumetric flow emerges. A complementary sensor signal (in the case of a reed contact, a sensor signal resulting from a low impedance of the signal circuit) means that the filter unit 10 is no longer continuous and therefore has to be replaced. Depending on the type of sensor 26, 28, a different coding of the rest position of the flap 20 or the deflected from the rest position flap 20 may result. It is essential that a signal obtainable by means of the sensors 26, 28 is an automatically evaluable criterion for whether the flap 20 is in the rest position or not and thus also an automatically evaluable criterion for whether the filter unit 10 is replaced should. In general, the sensor signal is thus a sensor signal which indicates a so-called loading state of the respective filter unit 10.

The representation in FIG. 2 shows a further embodiment of the innovation suggested here. In place of the filter module 10 shown in FIG. 1 as a filter unit 10, a pocket filter unit 10 functioning as a filter unit 10 with a plurality of so-called pocket filters / filter pockets occurs here. For receiving the filter unit 10, a filter unit housing 12 (housing 12) is provided, which has a frame-like circumferential contact surface 32 in the area of its front side 22, which limits an insertion depth when the pocket filter unit 10 is pushed into the housing 12.

The illustration in FIG. 2 illustrates that, as already mentioned, it does not depend on the type of filter unit 10 located in housing 12 or insertable into housing 12. The innovation proposed here can be used with a wide variety of filter units 10 and accordingly applies to the interpretation of the description presented here that even with the mention of a concrete filter unit 10 other conventional filter units 10 are always read and as of the description presented here should apply.

In the embodiment according to FIG. 2, the flap 20 is articulated on the housing 12 in the form of a strip-shaped flap 20. With regard to the mobility of the flap 20, this applies previously in the description of the embodiment according to FIGS. gur 1 said. A volumetric flow passing through the filter unit 10 strikes the strip-shaped flap 20 at least in part and at least partially passes the strip-shaped flap 20 laterally. A strip-shaped flap 20 with a surface which is rather small in comparison to the total area of the rear side 24 of the housing 12 is particularly suitable for filter units 10, through which a comparatively high volume flow passes in the unloaded state, thus, for example, a filter unit 10 with a plurality of so-called pocket filters / Filter bags. On the position of the flap 20 is not important. The flap 20 may be located approximately in the center of the rear side 24 of the housing 12, but also eccentrically or at the edge of the opening in the back 24 of the housing 12. As sensors 26, 28 is a sensor into consideration, as previously explained in the description of the embodiment of Figure 1.

The illustration in FIG. 3 shows yet another embodiment of the innovation proposed here. The embodiment is shown on the basis of a filter unit 10 with a plurality of so-called pocket filters / filter bags, so that reference can be made to the explanation in FIG. In this embodiment too, the type of filter element 10 does not matter, and also in this embodiment, an automatically evaluable signal can be generated by means of a corresponding air flow sensing device 20, which indicates whether the respective filter unit 10 is still continuous or should be replaced , So a signal indicating the loading state of the filter unit 10. In the illustration in FIG. 3, this is an exemplary T-shaped flap element 20 functioning as an air flow sensing device 20, which is referred to below as a flap 20 (corresponding to the terminology used in the description of the embodiment in FIG. 1) becomes. The end of the flap 20 or an optional horizontal part of the T-shaped flap 20 extends, for example, into the center of the rear side 24 of the housing 12 and is exposed there to the volume flow passing through the filter unit 10, for example the volume flow passing through the bag filter unit 10 , Such a volume flow leads to a deflection of the flap 20 or to a deformation of the vertical part of the flap 20. A deflection of the flap 20 can be sensed, for example, in an automatically evaluable manner if the two sensor components 26, 28 together form a switch which opens or closes a sensor circuit in the case of a deflected flap 20. For example, the flap 20 "stands" on a kind of rocker switch of a switch and actuates it as a function of the deflection state. Alternatively, a deflection of the flap 20 in an automatically evaluable manner can be sensed if, for example, the sensor component 28 located on the housing 12 is a pressure-sensitive sensor component 28, in particular a piezoelement on which the vertical part of the T shaped part of the flap 20 so to speak, "stands" so that on the surface of the pressure-sensitive sensor component 28 at a deflection of the flap 20 in comparison to a non-deflected flap 20 different force acts, for which the pressure-sensitive sensor component 28 generates a proportional and automatically evaluable sensor signal ,

A deformation of the flap 20, in particular a deformation of the vertical part of the T-shaped flap 20, can be sensed in an automatically evaluable manner, for example, if the flap 20 as a whole or its vertical part is made of an electroactive polymer or has a layer (surface or sandwiched surface portion) with an electroactive polymer. Electroactive polymers (EAP) are known per se. When applying an electric field to such a material results in a change in shape of the material. Likewise, a change in shape of the material due to an external force effect leads to a change in an electrical voltage that can be measured across the material. When creating a rule electrical field to such a material, this acts as an actuator. When measuring an electrical voltage across the material, this acts as a sensor. Here is the function as a sensor in the foreground. A deformation of the vertical part of the T-shaped flap 20 due to an inflowing volume flow leads to a shortening of the surface facing away from the volume flow and to a corresponding increase in the (measured in the vertical direction) length of the volume flow surface facing and thus to a length change the covered by the flap 20 layer with the electroactive Material. A measurable due to such a change in length electrical voltage across the layer with the electroactive material is evaluated as a measure of the type of deformation of the flap 20 and a deformation of the flap 20 means a deflection of the flap 20 from its rest position. Without such a deformation, the flap 20 is in its rest position. Again, an automatically evaluable sensor signal is given, which is an indica gate for the loading state of the filter unit 10 and thus an indicator of whether a filter unit 10 should be replaced.

Electroactive polymers or the like are also considered as sensors in the embodiment shown in Figure 1 and Figure 2 into consideration. For example, the hinge element 30 can be realized by means of an electroactive material and the deflection of the flap 20 can be sensed directly on the hinge element 30. Alternatively, the flap 20 can be made of an electroactive material or have at least one layer (surface or sandwiched surface portion) with an electroactive material. Then the articulation of the flap 20 is stiffer, so that deformation of the flap 20 is possible due to an oncoming volumetric flow, wherein the deformation leads to a change in length of the layer with the electroactive material and the change in length to an electrically evaluable signal change.

The representation in FIG. 4 shows a further embodiment of the innovation suggested here. As a filter unit 10, a pocket filter unit 10 is again shown (see FIG. 2, FIG. 3), and here too it holds true that any other conceivable filter unit 10 is also suitable. The housing 12 has on its rear side 24 as Luftströmungsfühlvorrichtung 20 a rotatable impeller (rotor) 20 with individual "wings" (blades, rotor blades) on. In the embodiment shown, the impeller 20 is arranged in a basically optional manner at the end of a cantilever 34, so that the impeller 20 is in the region of the center of the rear side 24 of the housing 12 and is there exposed to the tetrereinheit through the filter unit 10 volume flow, so for example, the passing through the pocket filter unit I O volumetric flow. essential lent is that the impeller 20 is set at an inflowing flow in rotation. A rotating impeller 20 can act, for example, on a generator acting as a sensor component 26, which generates an electrical voltage as a function of the rotational speed of the impeller 20. In the case of such an impeller 20 located on the rear side 24 of the housing 12, this is set in rotation when a filter unit 10 located in the housing 12 is impinged on its inlet side 16 by a volume flow and the filter unit 10 still flows for the air flow at least partially permeable. A resulting from a rotation of the impeller 20 electrical voltage is then a measure of the permeability of the filter unit 10 and a voltage below a predetermined or predetermined threshold indicates a stationary impeller 20 or only a very low speed of the impeller 20 at. Such a sensor signal indicates that the filter unit 10 should be replaced.

The illustration in FIG. 5 finally shows that the air flow sensing device 20 can also be arranged on an input side of the filter unit 10 (in contrast to the previously shown situations in which the air flow sensing device 20 is arranged on an output side of the filter unit 10). Shown is an air flow sensing device 20 in a form as described in the explanation of the embodiment shown in Figure 3, so that reference is made to the description there. The air flow sensing device 20 is, for example, in particular replaceable, attached to a frame 36 of the filter unit 10 ters.

By means of the air flow sensing device 20, regardless of the mounting location (on an input side of the filter unit 10, on an output side of the filter unit 10), an air flow passing through the filter unit 10 can be detected when the air flow through a downstream of the filter unit 10 air / volumetric flow generating device, for example, a fan, is generated and the air / Volumenstromzeugungs- device sucks the air A / lumenstrom in a sense by the filter unit 10. Then, with a fresh filter unit 10, an air flow on the input side (here ambient air is drawn in) and on the outlet passage side (when the sucked ambient air passes through the filter unit 10 out). In the case of a filter unit 10 which is no longer continuous, no ambient air is drawn in on the input side and accordingly no air also passes through the filter element 10.

An airflow sensing device 20 (or a volumetric flow sensing device 20) is generally a device that responds to a volumetric flow, particularly an airflow. Individual possible embodiments of an airflow sensing device 20 are given here. A flap 20 acting as an air flow sensing device 20 responds to a volume / air flow by being deflected and / or deformed by the volume / air flow (embodiments of FIGS. 1, 2, and 3) and moving without a volume / air flow. Air flow is in a rest position. In another embodiment of an air flow sensing device 20 (or a volumetric flow sensing device 20), this responds to a volume / air flow by generating a volume / air flow-dependent electrical variable, in particular an electrical voltage (embodiment according to FIG. 4).

A sensor signal which can be detected directly or indirectly in a sensor circuit on which the respective airflow flow sensing device 20 acts can, for example, be used to control a signal element associated with the respective housing 12 (and thus the filter unit 10 located in the housing 12) , in particular an optical signal element, are used. The signal element may be associated with the respective housing 12 in which it is located directly on the housing 12 or in spatial proximity to the housing 12 (spatial assignment). The signal element may also be located at a distance from the housing 12, for example in a control panel, and is functionally assigned to the respective housing 12 by a respective position in the control panel. Similarly, it can also be provided in spatially remote signal elements that it is not at all a physical signal element, but rather a generated by means of a computer monitor or derglei Chen display. In the interests of better readability of the further description, such a display is also referred to as a signal element. An automatic activation of such a signal element taking place on the basis of a corresponding sensor signal indicates a loading state of the filter unit 10 located in the housing 12, which necessitates an exchange of the filter unit 10. The replacement of a filter unit 10 can therefore now take place very exactly when an exchange is actually necessary. In the case of a multiplicity of filter units 10 arranged, for example, above and / or next to one another in their own housing 12, it is now possible for each filter unit 10 to be replaced precisely when this is necessary. Here, for example, it may be shown that a necessary exchange is indicated in the case of a filter unit 10, while in the case of a neighboring filter unit 10 no replacement is required. So far, adjacent filter units 10 have been regularly replaced upon detection of a filter unit 10 with a critical loading condition, although this may not have been necessary. In addition, it should be noted that a detection of a loading state of a filter unit 10 has heretofore required that an operator take a sample, for example. This is expensive. In order to avoid such an expense, it has hitherto been quite usual to exchange all filter units 10 of a system or a system component at regular intervals, although this might not have been necessary and / or although this may not be the case for all filter units 10 would have been necessary.

The unit referred to above as the housing 12 may be part of the respective filter unit 10, but may also act as a receptacle for a filter unit 10 (possibly comprising its own housing / frame). This is explained using the example of a paper gauze filter module according to EP 2 532 409 A: The paper gauze filter module comprises a multi-folded paper layer, which is received by an outer frame acting as a housing. As a filter unit 10 in the sense of the above statements, on the one hand, the entire Papiergelegefiltermodul, but on the other hand, only the Papiergelege the Papiergelegefiltermoduls be understood. When the entire paper jelly filter module is considered as a filter unit 10, a housing 12, for example a compartment in a filter wall or a compartment in a device according to EP 3 062 909 B, accommodates the paper jelly filter module (the filter unit 10). The sensors 26, 28 are then located completely (embodiments according to FIG. 3 and FIG. 4) or at least partially (embodiment according to FIG. 1 and FIG. 2) on such a housing, in particular on such a compartment.

If the paper scrim located inside the paper scrubber module is considered as a filter unit 10, the filter unit 10 itself has a housing 12, namely in the case of a paper scrubber module according to EP 2 532 409 A, the frame in which the paper scrim is inserted. The paper gauze filter module (the filter unit 10) may be inserted into another housing 12, together with the housing 12 (the frame) enclosed therewith, for example - as described above - in a compartment in a filter wall or in a compartment of a device according to the EP 3 062 909 B. In this variant, so to speak, two housings 12 are to be considered. On the one hand, an "inner" housing 12 belonging to the filter unit 10 and, on the other hand, an "outer" housing 12 belonging to a higher-level device, for example a filter wall or a device according to EP 3 062 909 B. As location The sensor 26, 28 or as a location of parts of the sensor 26, 28 is both such an inner housing 12 as well as such an outer housing 12 into consideration. The sensors 26, 28 are therefore also in this variant entirely (embodiments according to FIG. 3 and FIG. 4) or at least partially (embodiment according to FIG. 1 and FIG. 2) on such an inner housing 12 or on such an outer housing 12th

Based on the above, the general description of the innovation proposed here, namely

System comprising a housing 12 for receiving a filter unit 10, with a filter unit 10 inserted into the housing 12 or insertable into the housing 12, and with an air flow sensing device 20 on an outlet The device 18 can be generated by means of the Luftströmungsfühlvor- device 20 an automatically evaluable signal indicating a nen loading state of the filter unit 10 in the case of a filter element in the form of a filter unit 10 with its own housing 12, so for example one Filter unit 10 in the form of a Papiergelegefil- module according to EP 2 532 409 A, also be written as follows:

Filter element with a filter unit 10, with a unit 12 for receiving the filter unit 10 and with an air flow sensing device 20 on an output side 18 of the filter element, wherein by means of the air flow sensing device 20 is an automatically evaluable signal can be generated bar, which is a loading state of the filter unit 10 and in the case of a filter unit 10 which is used with or without its own housing 12 in a compartment or the like of a higher-level apparatus, for example a filter wall or a device according to EP 3 062 909 B, also be written as follows:

System comprising at least one box-like compartment or the like for receiving a filter unit 10, with a filter unit 10 inserted into the compartment or insertable into the compartment, and with an airflow sensing device 20 on an exit side 18 of the filter unit 10, wherein the air flow sensing device 20 is a automatically evaluable signal can be generated, which indicates a loading state of the filter unit 10.

In the former case ("filter element with a filter unit ..."), the filter element itself is the "system with a housing of the more general description. In the second case, the filter element is part of a system receiving the filter element.

The innovation proposed here thus makes an important contribution to the efficient utilization of the capacity of individual filter units 10. The innovation helps avoiding unnecessary waste in the form of filter units 10 which have been replaced too early, and thus also reduces the operating costs of a plant or a plant part in which at least one filter unit 10 of the type mentioned at the beginning or a plurality of such filter units 10 is used, to lower.

The air flow sensing device 20 thus functions as a filter signaling device, namely directly or indirectly as a device which indicates a loading state of the respective filter unit 10. The air flow sensing device 20 is located on the output side 18 of the monitored by means of the air flow sensing device 20 filter unit 10. There, the air flow sensing device 20 is not in contact with, for example, of the respective volume flow entrained Farbparti- angles and so does not pollute. Accordingly, the air flow sensing device 20 can be used over the long term and requires no or at least no significant cleaning and / or maintenance measures.

Individual aspects in the foreground of the description presented here can be briefly summarized as follows: A system is specified with a housing 12 for accommodating a filter unit 10, with a filter unit 10 introduced into the housing 12 or insertable into the housing 12, and with an ner air flow sensing device 20 on an output side 18 of the filter unit 10, wherein by means of the air flow sensing device 20 is an automatically evaluable signal can be generated, which indicates a loading state of the filter unit 10. Furthermore, a use of such an air flow sensing device 20 is indicated, namely a use in which the air flow sensing device 20 in such a system indicates a loading state of the filter unit 10. Also provided is an airflow sensing device 20 functioning as an indicator of a loading condition of a filter unit 10, which is intended for use in such a system. Finally, various embodiments of such air flow sensing devices 20 are given. LIST OF REFERENCE NUMBERS

10 filter unit, filter module, bag filter unit

12 Filter unit housing, housing, compartment

14 filter module frame

 16 streamed side, input / front side

18 output / back

 20 Air flow sensing device, flap, impeller

22 front side (of the housing)

 24 back side of the case

 26 sensor component

 28 sensor component

 30 hinge element

 32 contact surface

 34 outriggers

 36 frames

Claims

claims

1. System comprising a housing (12) for receiving a filter unit (10), with an inserted into the housing (12) or in the housing (12) insertable filter unit (10) and with an air flow sensing device (20) on an input - or output side (18) of the filter unit (10), wherein by means of Luftströ- ment sensing device (20) an automatically evaluable signal can be generated, which indicates a loading state of the filter unit (10).

2. System comprising at least one box-like compartment (12) for receiving a filter unit (10), with an inserted into the compartment (12) or in the compartment (12) insertable filter unit (10) and with an air flow sensing device (20) on an input - or output side (18) of the filter unit (10), wherein by means of the air flow sensing device (20) an automatically evaluable signal can be generated bar, which indicates a loading state of the filter unit (10).

A filter element comprising a filter unit (10) having a housing (12) for receiving the filter unit (10) and an airflow sensing device (20) on an input or output side (18) of the filter element, the air flow sensing device (20) an automatically evaluable signal can be generated, which indicates a loading state of the filter unit (10).

4. System according to one of claims 1 or 2 or filter element according to claim 3, wherein as the air flow sensing device (20) a deflectable flap (20) acts.

5. System according to any one of claims 1 or 2 or filter element according to claim 3, wherein as the air flow sensing device (20) an impeller (20) acts.

6. System according to one of claims 1, 2 or 4 or filter element according to claim 3, wherein the air flow sensing device (20) as a sensor (26, 28) comprises a layer with an electroactive polymer.

7. An air flow sensing device (20) functioning as an indicator of a loading state of the filter unit (10) in a system or a filter element according to any one of the preceding claims.

8. Air flow sensing device (20) according to claim 7 in the form of a deflectable flap (20).

9. Air flow sensing device (20) according to claim 7 or 8 and having a layer with an electroactive polymer as sensor (26, 28).

10. Air flow sensing device (20) according to claim 7 in the form of an impeller (20).